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I Can Feel Your Pain:
Haptic Roughness Promotes Empathy and Helping Behaviors
CHEN WANG
RUI (JULIET) ZHU
TODD C. HANDY
Paper is Currently under Review. Please Do NOT Cite or Circulate without Authors’ Permission
Chen Wang ([email protected]) is a doctoral student in marketing, Rui (Juliet) Zhu
([email protected]) is Canada Research Chair, Alumni Professorship, and associate
professor of marketing, both at the Sauder School of Business, University of British Columbia,
Vancouver, BC, Canada V6T 1Z2. Todd C. Handy ([email protected]) is Associate Professor
at the Department of Psychology, University of British Columbia, Vancouver, BC V6T 1Z4.
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ABSTRACT
Eliciting help has important social impacts. However, we know little about how incidental,
contextual cues can encourage helping behaviors. In a series of laboratory and field studies, we
show that incidental exposure to haptic sensation of roughness (vs. smoothness) promotes
empathy and consequently enhances helping towards unfamiliar targets. In addition, using direct
measures of brain activity, we provide important insight to the process by suggesting that haptic
roughness increases attention to others’ misfortune, and therefore leads to enhanced empathetic
responses at later, evaluative (vs. earlier, automatic response) stages. These findings not only
underscore the power of subtle contextual cues on shaping important behaviors, but also point to
the possibility of developing novel intervention strategies for promoting human prosociality.
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From Japan’s 9.0 magnitude earthquake and the ferocious tsunami, to the Aids epidemic
in Africa, to the suffering patients around the globe looking for cure, to the homeless in every
neighborhood, many people are desperately waiting for help. Yet eliciting help has never been
easy (U.S. Bureau of Labor Statistics 2010). While extensive research has examined why people
help and how to promote helping, much has focused on potential donors’ demographic and
psychographic characteristics (Harvey 1990; Loewenstein and Small 2007), identity (Aaker and
Akutsu 2009), and motivation (Dovidio, Allen, and Schroeder 1990; Dunn, Aknin, and Norton
2008). We know little about how incidental, contextual cues can affect helping behavior
(Bendapudi, Singh, and Bendapudi 1996). However, if we can start identifying inherently non-
social factors that may influence pro-social behaviors, this may lead to novel approaches for
facilitating the massive humanitarian needs of our complex, modern world. Although some early
investigations have identified certain environmental factors, such as ambient fragrance (Baron
1997) and music (North, Tarrant, and Hargreaves 2004), we believe the current research is the
first work to identify a haptic variable, namely, the haptic sensation of roughness, and investigate
its impact on helping behaviors.
The sense of touch (i.e., haptics) provides us with one of the most fundamental means to
acquire information and to connect with the external world. Yet historically, despite its
importance and ubiquity in our subjective experience, haptic sensations have received little
attention in behavioral research (Ackerman, Nocera, and Bargh 2010; Field 2010; Peck and
Childers 2008). Existing research in haptics has primarily focused on the issue of the presence
versus absence of touch. These factors include object attributes that encourage touch (Grohmann,
Spangenberg, and Sprott 2007; Krishna and Morrin 2008; McCabe and Nowlis 2003), individual
differences in the need for touch (Citrin et al. 2003; Peck and Childers 2003a, 2003b), situational
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factors that motivate touch (Peck and Childers 2008; Peck and Shu 2009; Peck and Wiggins
2006), and interpersonal touch (Crusco and Wetzel 1984; Erceau and Guéguen 2007; Fischer et
al. 1976; Hertenstein, et al. 2006; Martin 2012; see Gallace and Spence 2010 for a review). Yet,
little attention has been directed to examine the haptic attributes (i.e., texture, hardness, weight,
and temperature; Klatzky and Lederman 1992, 1993; Lederman and Klatzky 1987), while touch
is always present. Within the limited research that examines the haptic attributes, most has
focused on the psychophysical aspects, for example, arious ph sical factors contri uting to
human’s tactile roughness perception peault, et al. 009 Lawrence et al. 2007), without
shedding light on the influence of haptic attri utes on people’s eha iors. Recently, some
exciting work has begun to reveal that haptic experiences can have a significant impact on social
evaluative processes (Ackerman, Nocera, and Bargh 2010; Williams and Bargh 2008). For
example, holding a resume attached to a heavy clipboard leads people to think the job candidate
as more important, touching rough sandpaper makes individuals judge an unrelated social
interaction being difficult (Ackerman, Nocera, and Bargh 2010), and holding a cup of hot coffee
causes people to perceive another person as having a warm personality (Williams and Bargh
2008). The current research seeks to add to this line of research by proposing that haptic
experiences can also affect indi iduals’ helping behavior in an unrelated context.
We propose that exposure to rough haptic surfaces may positively impact helping
behaviors. We argue that this should happen because haptic roughness is likely to enhance
attention to other’s misfortune. Such heightened attention ma trigger empathetic responses
towards the needy others (Lamm et al. 2007; Singer and Lamm 2009), which leads to greater
helping behaviors (Bagozzi and Moore 1994; Baston 1991; Hoffman 1982). By exploring these
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hypotheses, we not only wish to contribute to the literature on haptics, but also seek to shed light
on how non-social factors, such as haptic experience, may influence people’s helping behaviors.
THEORETICAL BACKGROUND
The Impact of Haptic Sensation on Helping Behaviors
We first posit that haptic sensation of roughness, compared to smoothness, enhances
empathy, which is the key antecedent of helping behavior. We suggest that this should happen
because haptic roughness, which is known to cause mild discomfort (Lederman 1983), is likely
to enhance attention to other’s misfortune. Such heightened attention can subsequently result in
enhanced empathy towards needy others. This argument finds support in converging evidence
from neuroscience and social psychology.
Surface roughness is a very salient attribute for touch. In fact, it is much more salient than
other haptic attributes such as form or size (Klatzky, Lederman, and Reed 1987). When touching
a coarse surface, the friction between the finger and the surface may cause individuals to
experience mild discomfort (Lederman 1983). This minor discomfort is likely to enhance
attention to others’ discomfort, misfortunes, or challenges. To support this argument, we provide
direct e idence in stud measuring participants’ rain acti it when the were experiencing
haptic roughness (vs. smoothness). Further, prior research has suggested that attention to a social
target is required for triggering empathetic experience (Lamm et al. 2007; Singer and Lamm
2009). It has also been revealed that empathy responses in the brain can be triggered by
perceiving or imagining the emotional states of others e.g., seeing someone else’s pain), in
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particular, when our attention is directed to the targets (Decety and Lamm 2006; Singer, et al.
2004). For instance, in an fMRI study by Gu and Han (2007), when participants saw pictures of
hands in painful situations, they showed activation in the same brain areas that would get
activated if they experienced the pain firsthand. However, when participants’ attention was
distracted away from the inflicted pain, no activation in those brain areas was observed.
Similarly, in a follow-up EEG study by Fan and Han (2008), whose paradigm we adopted in
study 2, they also demonstrated that attention to the stimuli directl modulates participants’
empathetic responses. Taken together, the above literature supports our argument that haptic
roughness (vs. smoothness), which may enhance attention to other’s misfortune, can promote
empathy towards the needy other.
After establishing the link between haptic roughness and empathy, we next reason that
the increased empathy elicited by haptic roughness leads to greater helping behavior.
Conceptually, empathy has been defined as the attempt to comprehend unjudgmentally the
positive and negative experiences of another person (Wispé 1986), by experiencing and
understanding another person’s affecti e or ps chological state i.e., put oneself in another
person’s shoes Kre s 1970; Eisenberg and Miller 1987; Zahn-Waxler and Radke-Yarrow 1990).
Further, the positive association between empathy and prosocial behavior has been well
established in the literature (Bagozzi and Moore 1994; Baston 1991; Batson et al. 1997; Coke,
Batson, and McDavis 1978; Hoffman 1982).
Summarizing the above theorizing, we propose that haptic sensation of roughness,
compared to smoothness, results in greater empathy towards the needy others, thereby leading to
increased helping behaviors. Formally,
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H1: The haptic sensation of roughness ersus smoothness leads to people’s greater
willingness to help.
Interpersonal Familiarity and Empathy
The existing literature on prosocial behaviors consistently shows that interpersonal
familiarity between the potential helper and the helping target tends to promote empathy and thus
prosocial behaviors (Loewenstein and Small 2007). For instance, Small and Simonsohn (2008)
show that a personal connection with a close victim (e.g., a friend or a loved one), or even the
close relationship carried over to other victims suffering the same misfortunes as their friends
and loved ones, promotes greater empathy and helping behaviors. Along the same lines, people
are more likely to help the victims who are similar to themselves (Hornstein 1976; Krebs 1975),
or belong to their in-group rather than their out-group (Dovidio et al. 1997; Flippen et al. 1996).
According to Batson and his colleagues, reducing social distance and inducing empathy by
asking individuals to take the need person’s perspecti e leads to greater altruistic behaviors
(Batson, Early and Salvarani 1997; Batson et al. 2003; Coke, Batson, and McDavis 1978).
Building upon the above findings, we propose an important boundary condition for the
aforementioned main effect of the haptic roughness on people’s helping eha iors. Specifically,
when the potential helper is unfamiliar with the helping target, we should observe the
aforementioned main effect, namely, haptic roughness versus smoothness should enhance
empathy and thus helping behavior. However, if the potential helper is familiar with the helping
target, the helper should experience heightened empathy level and be willing to help regardless
of the haptic sensations. Formally stated,
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H : The haptic sensation of roughness ersus smoothness leads to people’s greater
willingness to help towards an unfamiliar target; but this effect mitigates towards
a familiar helping target.
Further, because both haptic roughness and interpersonal familiarity produce empathy, we
posit that smooth versus rough haptic sensations as well as familiar versus unfamiliar
relationship harbor differential abilities to garner empathy that influence helping behaviors. In
other words, the interactive effect of haptic sensation and interpersonal familiarity leads to
different le els of empath , which, in turn, affects people’s willingness to help. Formally,
H3: The interactive effect of haptic sensation and interpersonal familiarity on
willingness to help is mediated by empathy.
In what follows, we report a series of six studies to test our theory. Study 1 establishes
the basic main effect that the haptic sensation of roughness versus smoothness is more likely to
promote helping behaviors (hypothesis 1). Study 2 uses direct measures of brain activity to
provide insights into the underlying mechanism that exposure to haptic roughness may enhance
attention to others’ misfortunes. Study 3 demonstrates the moderating role of familiarity in the
relationship between haptic sensations and helping behavior (hypothesis 2). Study 4 further
probes the underlying process and finds support that the interactive effect between haptic
sensation and interpersonal familiarity is mediated by empathy (hypothesis 3). Study 5 provides
additional support for the mediating role of empathy by showing that the interaction between
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haptic sensation and interpersonal familiarity only occurs for low empathizers. Finally, study 6
provides external validity for our laboratory results with field data from a street fundraising event.
STUDY 1: HAPTIC ROUGHNESS LEADS TO GREATER DONATION
In study 1, we directly tested the hypothesis 1 that haptic roughness enhances helping
behaviors. We manipulated the haptic sensations by two different kinds of hand washes under
the cover story of a product evaluation task. The key dependent measure was the participants’
willingness to donate in a subsequent task. We predicted that haptic sensation of roughness
versus smoothness would lead to greater donate intention.
Method
Sixty-seven undergraduate students participated in the experiment for course credit. We
employed a one factor 3 (haptic sensation: smooth vs. rough vs. control) between-subject design.
The study was run in small groups of no more than four people per session. Upon arrival,
participants were randomly assigned to one of the three haptic conditions, and were led to
individual workstations. The workstations were separated from each other by dividers, such that
participants could not see each other during the study. On each workstation for the rough and
smooth conditions, there were a basin of water, a bottle of hand wash, a clean and dry towel, and
a computer. Only a computer was present for the control condition.
Participants in the rough and smooth conditions first performed the haptic manipulation
under the disguise of a product evaluation task. They were asked to experience and evaluate one
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of the two hand washes that varied only in texture (smooth vs. rough), but were identical in terms
of color and scent. Specifically, in the smooth condition, the hand wash was a moisturizing hand
wash containing vitamin E and aloe, whereas in the rough condition, the hand wash was a scrub
hand wash containing exfoliating microbeads. Participants were instructed to wet their hands
first with water, squeeze two drops of the hand wash on their hands, and then feel the hand wash
very carefully by rubbing it between their fingers for 20 seconds. Then they cleaned their hands
and answered two filler questions on the computer regarding their attitudes towards the hand
wash. Participants in the control condition did not perform this task.
Next, all participants were asked to do an allegedly unrelated willingness-to-donate task
on the computer, which measured our key dependent variable. They were presented with
information about two fictitious non-profit organizations, “Leadership Camp” and “U Fit”, one
on each screen, and were asked to indicate their willingness to donate to each charity. We used
fictitious charities to avoid prior knowledge and preference towards any existing ones.
Finally, participants completed a manipulation check and a mood measure. The
manipulation check assessed the effectiveness of the haptic experience manipulation by asking
participants to rate on two questions i.e., “Recall the hand wash you used at the beginning of the
stud . To what extent did it make our hands feel smooth and soft?” and “To what extent did the
hand wash make our hands feel rough and coarse?”). The mood measure included six randoml
ordered adjectives, three representing positive mood (i.e., happy, excited, and cheerful) and the
other three representing negative mood (i.e., sad, upset, and depressed). All items were on 7-
point scales (1 = not at all; 7 = very much). The study ended with a suspicion probe by asking
participants the true purpose of the study.
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Results and Discussion
To check the manipulation, an index for roughness was created by averaging the rating of
roughness and the reversed rating of smoothness of the hand wash (α = .91). The result of a one-
way ANOVA confirmed that the scrub hand wash indeed felt rougher (M = 5.04) than the
moisturizing hand wash (M = 2.68, F(1,43) = 18.13, p < .0001).
To test our main hypothesis, we first created a composite score for the willingness to
donate, by averaging the ratings for two charities α = .75). As anticipated, one-way ANOVA
revealed a significant main effect of haptic experience (F(2,64) = 6.14, p < 0.01), such that those
in the rough condition (M = 4.30) indicated greater willingness to donate than both those in the
smooth condition (M = 2.86, t(64) = 3.16, p < .01), and those in the control condition (M = 3.00,
t(64) = 2.86, p < .01). The contrast between the latter two conditions was not significant (t(64)
= .30, p > .70). These results thus supported our hypothesis that rough haptic sensation can
facilitate helping behaviors.
To examine whether the haptic manipulation altered indi iduals’ mood states, we created
two indices by averaging the three positive mood items (α = .76), and the three negative mood
items (α = .78). One-way ANOVA revealed that the haptic manipulation did not affect positive
(Msmooth = 4.70, Mrough = 4.57, Mcontrol = 4.59; F(2,64) = .17, p > .84), or negative mood (Msmooth =
1.70, Mrough = 1.64, Mcontrol = 1.80; F(2,64) = .33, p > .72). We also measured mood in studies 3,
4, and 5, and in none of the studies did we observe a significant mood effect. Thus, we do not
report this mood measure in later studies. Finally, no one showed suspicion about the connection
between the ostensible product evaluation task and the donation task.
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The results of this study supported hypothesis 1 that the haptic sensation of roughness
enhances helping behaviors. In the next study, we explored the underlying process. In particular,
we used direct measures of brain activity to demonstrate that haptic roughness may enhance
attention to other’s misfortune in the stimuli.
STUDY 2: BRAIN ACTIVITY WHEN EXPERIENCING HAPTIC ROUGHNESS
The purpose of study 2 was to test our hypothesis that exposure to haptic roughness may
promote empathy and helping behavior by triggering indi idual’s enhanced attention to other’s
misfortune. Recent research in neuroscience has found that attention to a social target is required
for triggering an empathetic experience (Lamm et al. 2007; Singer and Lamm 2009). Further, the
empathetic responses to other’s misfortune have been temporally dissociated into two distinct
processes – an initial automatic response of mirroring the physical discomfort itself, followed in
time by a more deliberate appraisal of the painful context (Decety and Lamm 2006; Fan and Han
2008; Goubert, et al. 2005). If haptic roughness can indeed enhance attention to socially-relevant
stimuli and promote empathy, we predicted that it should affect these later, evaluative aspects of
empathy, owing to the known modulatory effects attention has on them (Fan and Han 2008). To
test this, we used direct measures of brain activity by replicating Fan and Han’s 008) paradigm,
in which they recorded event-related brain potentials (ERPs) to investigate the temporal
mechanism of neural acti ities underl ing empathetic responses towards seeing other’s pain.
Method
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A total of 16 healthy students (8 males, 8 females) served as paid participants in the study.
All had no neurological or psychiatric history, were right-handed, had normal or corrected-to-
normal vision, and were not color blind.
The task required participants to briefly view digital color images of hands in various
action sequences (e.g., cutting vegetables, shutting doors), and to make a forced, two-choice
response for each image––did it appear painful or non-painful. Their brain's electrical responses
were recorded via ERPs as they were observing the images. The images were the "cartoon"
image set used originally by Fan and Han (2008), and depicted the hands from a first-person
perspective. Twenty images showed hands in "painful" positions (e.g., a hand trapped in a door),
and twenty showed hands in "neutral" positions similar to the "painful" condition, but not
implying pain (e.g., a hand next to a door). The images themselves were presented on the center
of a black computer screen. There were 40 trails (20 pain pictures and 20 neutral pictures) in
each trial block, and participants were run in 16 blocks in total. On each trial, the stimulus was
displayed for 500 ms and then followed by a fixation cross with a duration varying randomly
between 2400 and 2600 ms. The order of images was randomized between blocks and
participants. Responses were made via a response device held with both hands; half of the
participants signaled "painful" and "non-painful" via responses with the left and right thumbs,
respectively, and the other half performed the task with the reverse thumb-response mapping.
To manipulate haptic roughness versus smoothness, the hand-held response device was
placed in a small, shallow box made out of 60-grit sandpaper (rough condition) or vinyl paper
(smooth condition). The response device and box were held with both hands, such that the
thumbs were on top of the response device and positioned to hit the respective response buttons,
and the fingers were all holding the bottom of the box and making direct contact with the box
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surface. Participants alternated the box for each trial; the order (rough vs. smooth box first) was
counterbalanced between participants.
Electroencephalograms (EEGs) were recorded from 32 active electrodes (Bio-Semi
Active2 system) distributed evenly over the head at locations based on a modified version of the
International 10-20 System, relative to two scalp electrodes located over medial-parietal cortex
(CMS/DRL), using a second order high-pass filter of 0.05 Hz, with a gain of 0.5 and digitized
on-line at a sampling rate of 256 samples-per-second. Additional electrodes were also recorded
from the left and right mastoids, for later re-referencing of scalp signals. To ensure proper eye
fixation and allow for the correction and/or removal of events contaminated by eye movement
artifacts, vertical and horizontal electro-oculograms (EOGs) were recorded for all participants.
The vertical EOG was recorded from an electrode inferior to the right eye, and the horizontal
EOG from an electrode on the right outer canthus.
Results and Discussion
Electrophysiological results. Off-line, computerized artifact rejection was used to
eliminate trials during which detectable eye movements, blinks, and muscle potentials occurred.
Off-line artifact rejection was based on exceeded min-max difference thresholds within a -200 to
800 ms time window around each e ent for e e and muscle artifacts), with each participant’s
threshold scaled via data visualization to the ambient level of that participant's EEG noise. Prior
to signal a eraging of the EEG, each su ject’s ERP wa eforms were alge raicall re-referenced
to the average of the left and right mastoid signals and low-pass Gaussian filtered (25.6 Hz half-
amplitude cut-off) to eliminate high-frequency artifacts in the waveforms. The resulting single-
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subject ERPs were used to derive group-averaged waveforms for display and analysis. Statistical
quantification of ERP data were based on mean amplitude measures relative to a -200 to 0 pre-
stimulus baseline.
ERP data analysis focused a priori on frontal/central electrode sites CZ and FCZ, the
scalp region previously showing modulations in the empathetic responses to painful vs. neutral
images (Li and Han 2010). Statistical interrogation of the ERP waveforms were based on
repeated-measure ANOVAs on mean amplitude measures taken across three time windows of
analysis tailored to the morphology of the CZ/FCZ waveforms: a 250-500 post-stimulus window
capturing an N2 component, a 500-650 ms window capturing a P3-like component, and a 650-
800 ms window capturing an LPP-like component. The ANOVAs within each time window
included factors of image type (painful vs. neutral), haptic sensation (rough vs. smooth) and
electrode location (CZ vs. FCZ). For brevity and because we had no a priori predictions about
electrode location differences in the effects of image type and haptic sensation, we do not report
any main effects of electrode or interactions with the other factors. The results confirmed our
predictions (Figure 1). Consistent with Fan and Han (2008), the painful images elicited a
significantly greater mean amplitude compared to the neutral images across all three time
windows (250-500 ms: F(1,14) = 12.33, p < .005; 500-650 ms: F(1,14) = 6.78, p < .05; 650-800
ms: F(1,14) = 4.61, p < .05). More importantly, however, this heightened response to painful (vs.
neutral) images was amplified in the rough condition in the later time windows, as indicated by
the significant image type X haptic sensation interaction (500-650 ms: F(1,14) = 4.71, p < .05;
650-800 ms: F(1,14) = 4.78, p < .05). Specifically, in these later time windows, the sensitivity to
painful images was only evident in the rough condition (500-650 ms: t(14) = 9.65, p < .01; 650-
800 ms: t(14) = 14.90, p < .01), but not in the smooth condition (both ts < 2.8, both ps > .11).
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Insert figure 1 about here
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Behavioral results. We extracted and analyzed two measures of behavioral performance
in study 2. First, we wanted to examine the breakdown of "painful" versus "non-painful"
responses in each of the four stimulus conditions. Specifically, we calculated the proportion of
total responses in each condition that were "painful", and reported values in Table 1 (top). As
expected, there was a significant main effect of image type (F(1,15) = 1409.25, p < .001),
indicating the obvious tendency to respond "painful" more often to the painful (vs. neutral)
images. However, there was no main effect of haptic sensation (F(1,15) = .54, p = .82), nor a
haptic sensation X image type interaction (F(1,15) = .009, p = .93), indicating that haptic
experience had no impact on whether people reported the images to be painful or non-painful.
Second, we also wanted to examine the reaction times (RTs) to images as a function of
image type (painful vs. neutral) and haptic sensation (rough vs. smooth), as reported in Table 1
(bottom). In this analysis, RTs for each image were collapsed across "painful" and "non-painful"
responses. Although responses appeared to be slightly faster in the smooth vs. rough condition,
the effect was non-significant (F(1,15) = 1.51, p = .24). Again, there was no main effect of image
type (F(1,15) = .28, p = .60), or interaction between haptic sensation and image type (F(1,15) =
1.54, p = .24). This indicated that haptic sensation had no impact on the speed of participants'
categorical responses.
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Insert table 1 about here
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Discussion. In short, we noted that the effects of pain sensitivity and haptic sensation in
our ERP waveforms had no corresponding correlate in either of our primary behavioral measures
reported above ( % "painful" responses and RTs). Importantly, Fan and Han (2008) found a
similar data pattern – effects of painful vs. neutral images in ERP waveforms but not in RTs
between image types. This suggested that differential levels of implicit sensitivity to the painful
images (as captured in the ERP waveforms) did not appear to affect the category an image was
actually ascribed to (as captured by the % "painful" responses), nor the speed of image
categorization itself (as captured via RTs). Rather, given that we found a consistent positive
effect of haptic roughness on participants' willingness to help others, the dissociation in measures
in the current paradigm suggested a similar quantitative effect of haptic sensation on empathy-
related responding. That is, texture may not be affecting what looked painful vs. non-painful, but
instead, how painful or intense a painful image appeared to be.
Taken together, results from this study thus provided crucial evidence that haptic
roughness (vs. smoothness) may enhance empathy-related responses such as attention to the pain
or misfortune of others, and this effect appeared to be at later, evaluative stages of cognitive
analysis. Hence, by using disparate methods and measures, the first two studies directly
confirmed that non-social contextual factors can indeed affect our propensity for empathy and
willingness to engage in helping behaviors. However, does haptic roughness always lead to
greater helping intention? Given that helping behaviors are also subject to known social
influences, we suggested that the effects of haptic roughness may be modulated by social factors.
As such, study 3 introduced an important moderator to the main effect, namely, familiarity
towards the target.
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STUDY 3: DONATE TO FAMILIAR VERSUS UNFAMILIAR CHARITIES
Study 3 aimed to test hypothesis 2 by investigating the moderating role of target
familiarit on the effect of haptic roughness on people’s helping eha ior. Prior research
suggests that people experience enhanced empathy towards a familiar target (e.g., a friend, an
identifiable victim) and are more likely to help (Loewenstein and Small 2007; Small and
Simonsohn 2008). Thus, we reasoned that when individuals are familiar with the target, the
already heightened empathy would override any haptic effect, leading to comparably high levels
of helping behavior. But for unfamiliar target, we expected to replicate the main effect observed
in study 1.
Method
Forty undergraduate students participated in the study for course credits. The design was
a 2 (haptic sensation: rough vs. smooth) X 2 (target: familiar vs. unfamiliar) mixed design.
The procedure was similar to that of study 1, except a) we dropped the control condition,
and b) included both familiar (e.g., Aids.org) and unfamiliar charities (e.g., Sjögren's Syndrome
Foundation). Participants were asked to first perform a hand wash evaluation task to complete
the haptic manipulation. Next, all participants completed a willingness-to-donate task on the
computer. They were presented with four organizations, one at a time. Two organizations (i.e.,
National Breast Cancer Foundation and Aids.org) were selected as familiar charities, whereas the
other two organizations (i.e., Sjögren's Syndrome Foundation and Schizophrenia Foundation)
were chosen as unfamiliar ones. We included a short description for each charity, and the
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presentation order of the charities was randomized. For each charity, participants indicated their
willingness to donate at that moment on 7-point scales (1= not at all, 7 = very much).
Upon finishing the willingness-to-donate task, participants completed the manipulation
checks by indicating the roughness of the hand wash as per the questions in study 1, and by
rating the familiarity to each of the four charities. All items were measured on 7-point scales.
A pretest with 18 participants from the same population confirmed that the selected two
well-known charities were indeed more familiar to our participants than the two unknown ones.
Participants were presented with the same list of the charities and were asked to indicate their
familiarity towards each charity on 7-point scales. Two indices were created, one for the familiar
α = .78) and the other one for the unfamiliar α = .85) charities. Results indicated greater
familiarity with the two well-known (M = 5.92) than with the two unknown charities (M = 2.06,
t(17) = 14.43, p < .001).
Results and Discussion
The manipulation checks confirmed the effectiveness of our manipulations. As to the
haptic manipulation, the scrub hand wash felt rougher than the moisturizing hand wash (Ms =
4.78 vs. 2.80, F(1,38) = 11.03, p < .005). As to the familiarity manipulation, we created two
indices that summarized the average ratings for the well-known charities (α = .80) and the lesser-
known charities (α = .83). The results confirmed greater familiarity with the well-known
charities (M = 4.30) than with the lesser-known ones (M = 1.74, t(39) = 9.20, p < .001).
To analyze the dependent measure, we created two indices for familiar and unfamiliar
charities (α = .77, .82), respectively, by averaging the willingness to donate ratings. The two-way
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ANOVA revealed the anticipated interaction (F(1,38) = 6.69, p < .05; Figure 2), such that haptic
roughness (M = 4.98) led to greater willingness to donate than smoothness (M = 3.93) for the
unfamiliar charities (F(1,38) = 4.91, p < .05), but comparable levels of donation intentions for
the familiar charities (M = 5.00 vs. M = 4.98, F(1,38) = .00, p > .90).
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Insert figure 2 about here
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The results of this study demonstrated the moderating role of target familiarity on the
effect of haptic roughness on people’s helping eha iors (hypothesis 2). While haptic sensation
of roughness versus smoothness led to greater willingness to donate for lesser-known charities,
they resulted in equally high donation tendency for well-known charities. In the next study, we
examined whether empathy mediated this interactive effect between haptic sensation and target
familiarity on helping behavior.
STUDY 4: HELP A CONFEDERATE
The primary purpose of study 4 was to test hypothesis 3 by examining the mediating role
of empathy. In addition, we aimed to replicate the interaction observed in study 3 by using
another helping context and adopting a real behavioral measure (i.e., help a confederate to solve
some problems). This measure was modified from Weinstein and Ryan (2010, study 3).
Method
21
One hundred and two undergraduate students participated in the study for course credits.
The design was a 2 (familiarity: familiar vs. unfamiliar) x 2 (haptic sensation: smooth vs. rough)
between-subject design.
Each participant came to the lab individually. A confederate, who appeared as another
participant, came to the lab at the same time. Before the experiment, we verified that all the
participants were unacquainted with the confederate. In the lab, there were two desks next to
each other. On the desk, there were a basin of water, a bottle of hand wash, a cleaning and dry
towel, a computer, and a card with either letter A or B on it. Upon arrival, the participant and the
confederate were greeted by the experimenter and were then seated in front of each desk. The
confederate always sat at the desk with the letter A, while the participant always sat next to him
at the desk with the letter B. They were told that they were going to do a series of unrelated tasks.
For participants in the familiar condition, they were asked to first perform a
communication task with the confederate to increase familiarity between the dyad. The
communication task was an abridged version of the Relationship Closeness Induction Task,
which has been commonly used to generate relationships in a laboratory setting (Sedikides et al.
1999). The dyad was asked to engage in a natural conversation by asking each other two sets of
questions, each set for 5 minutes. The first set consisted of introductor questions such as “What
is our first name?”, and the second set consisted of more personal questions such as “What
would e the perfect lifest le for ou?”. The confederate was trained to pro ide the same
answers to different participants in the conversation. For participants in the unfamiliar condition,
they did not perform this communication task. Next, like in previous studies, all participants
completed the hand wash evaluation task which manipulated the haptic experience.
22
Having completed all the manipulations, the dyad was asked to do a creativity task
individually on the computer. Specifically, each person was given a different item and was asked
to generate as many usages as possible for the item. They were also presented with the following
information that created an opportunity for the participant to help the confederate:
“By a random draw, all As (i.e., those sitting at the desk A) will be eligible to be entered
in a competition to win a prize by generating the most usages of the given item, while all
Bs will NOT be eligible. If you are A, please try to generate as many solutions as possible
to win the prize. If you are B, you can either proceed with your own task, or help the A
sitting next to you generate more solutions to win the prize. If you choose to help, you can
terminate your helping at any time and go back to your own task.”
Therefore, the key dependent measure was whether the participant (i.e., always B in this context)
helped the confederate (always A) or not.
After this task, participants completed a short survey containing several measures. The
first one assessed their situational empathy level. Participants indicated, at this moment in time,
the extent to which s/he could project him/herself and understand the target person’s feelings in
two scenarios i.e., “Suppose that Am was diagnosed with cancer” and “Suppose that Bo won
a lotter of $ 000”). Next, to ensure that the familiarit manipulation was successful, we asked
participants to rate how much they feel psychologically close to the other participant, and how
much they like the other participant in this session, as per Sedikides et al. (1999). Finally, they
completed the same haptic experience manipulation check as detailed in study 1. All items were
assessed on 7-point scales (1 = not at all, 7 = very much).
Results
23
Manipulation checks. As to the haptic manipulation, again the scrub hand wash felt
rougher than the moisturizing hand wash (Ms = 4.71 vs. 2.81, F(1,100) = 33.19, p < .001). As to
the familiarity manipulation, the two familiarity measures were averaged to create a familiarity
index (α = .79). Results revealed that the confederate was indeed perceived as more familiar in
the familiar than the unfamiliar condition (Ms = 5.03 vs. 3.44, F(1,100) = 58.66, p < .001).
Decision on whether to help or not. Since the dependent variable was binary (i.e., help =
1, not help = 0), we conducted a binary logistic regression where the independent variables were
the participant’s familiarit towards the confederate, the haptic sensation t pe, and their
interaction term. As predicted, there was a significant interaction between the familiarity and the
haptic sensation (Wald χ2 = 5.78, p < .05). Specifically, when the participant was unfamiliar with
the confederate, he or she was more likely to help the confederate in the rough condition (61.5%)
than in the smooth condition (30.8%, χ2(1) = 4.95, p < .05; Figure 3a). By contrast, when the
participant was familiar with the confederate, he or she was equally likely to help the confederate
regardless of the haptic condition (80.0% s. 96.0%, χ2(1) = 3.03, p = .082; Figure 3b).
We further examined the helping duration when help was offered by the participant. A 2
(familiarity: familiar vs. unfamiliar) x 2 (haptic sensation: smooth vs. rough) ANOVA revealed
no significant treatment effect (ps > .24). This suggested that the haptic sensations may not have
an effect on the degree of the helping behaviors.
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Insert figure 3ab about here
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24
Mediated moderation analyses. Most importantly, we examined the mediating role of
empathy on the interactive effect of haptic sensation and target familiarity on helping likelihood.
Following the procedure recommended by Hayes (2012), we used the bootstrapping approach to
assess the mediated moderation. The 95% bias-corrected bootstrap confidence interval was
obtained using 5000 bootstrap samples. As predicted, the results demonstrated that the 95%
confidence interval did not include zero (.5110, 4.7357), indicating a significant mediating effect
of empathy on the interactive effect between familiarity and haptic sensation on decision to help.
Discussion
Study 4 provided support to hypothesis 3 by directly assessing indi idual’s situational
empathy level. Specifically, for an unfamiliar helping target, empathy inherent in the personal
connection was absent. Therefore, empathy elicited from the haptic roughness was driving the
effect, resulting in greater helping likelihood. By contrast, for a familiar helping target, empathy
inherent from the interpersonal relationship overrode empathy generated from haptic sensations,
leading to equally high helping likelihood. Moreover, the results replicated findings in study 3,
but using a different helping context and measuring real helping behavior.
STUDY 5: VOLUNTEER IN FURTHER EXPERIMENTS
This study aimed to provide further support for the mediating role of empathy by
measuring dispositional empathy. Further, we used another measure of helping behavior, i.e.,
participants’ willingness to assist the experimenter in further studies. This measure is widely
25
used in the literature to assess helping intentions (Greitemeyer and Osswald 2010; Nelson and
Norton 2005; Twenge et al. 2007). Familiarity and haptic sensation were manipulated in the
same way as in study 4. We predicted a three-way interaction between familiarity, haptic
sensation, and dispositional empathy. While we expected the same two-way interaction between
familiarity and haptic sensation as observed before among low empathizers, such an interaction
was not anticipated among high empathizers.
Method
Seventy-seven undergraduate students participated in the study for course credit. We used
a 2 (familiarity: familiar vs. unfamiliar) x 2 (haptic sensation: smooth vs. rough) x empathy
between-subject design. Dispositional empathy level was measured as a continuous variable.
Participants came to the lab individually. Upon arrival, the participant was asked to wait
for a late participant. Unbeknownst to them, no other participant was expected, but the waiting
time was used to conduct the familiarity manipulation. The participant either engaged in a
conversation as per RCIT with the experimenter (familiar condition) or waited silently
(unfamiliar condition). After 5 minutes, the participant was told that the session would start
without further waiting. The haptic manipulation was then implemented with the hand wash task.
After the manipulations were conducted, the participant was asked to take a 3-minute
break. At this moment, the experimenter handed over a short questionnaire, which asked the
participant to indicate whether s/he was willing to participate in future studies for free in order to
help the experimenter to complete her thesis. To avoid peer pressure and demand effect,
26
participants were asked to put the questionnaire aside once they finished. The questionnaire was
collected by the experimenter after the participant left the lab.
After the “ reak”, participants completed the Multi-Dimensional Emotional Empathy
Scale (Mayer, Caruso, and Salovey 1999), which assessed their dispositional empathy level.
Sample items are “I feel like cr ing when watching a sad mo ie” and “I feel happ when I see
people laughing and enjo ing themsel es”. The M EE Scale was measured on a 5-point scale (1
= strongly disagree, 5 = strongly agree). Finally, participants completed the haptic experience
and the familiarity manipulation checks on 7-point scales (1 = not at all, 7 = very much).
Results
Manipulation checks confirmed the effectiveness of the manipulations. Again, the scrub
hand wash felt rougher than the moisturizing hand wash (Ms = 4.97 vs. 2.66; F(1,75) = 36.79, p
< .001). The experimenter was perceived as more familiar in the familiar than the unfamiliar
condition (Ms = 5.09 vs. 3.80, F(1,75) = 26.08, p < .001).
To analyze the dependent measure, we coded the choice of whether to assist further
experiments as 1 versus 0, and conducted a binary logistic regression using haptics (smooth = 0,
rough = 1), familiarity (familiar = 0, unfamiliar = 1), dispositional empathy (continuous), and
all possible interaction terms on this choice measure. As predicted, the results revealed a
significant three-way interaction (Wald χ2 = 4.02, p < .05). Next, we used the SPSS macro
PROCESS developed by Hayes (2012) to probe the simple interaction at one standard deviation
above (i.e., high empathizers) and below (i.e., low empathizers) the mean of dispositional
empathy scores. Consistent with our prediction, spotlight analyses (Irwin and McClelland 2001)
27
revealed a significant two-way interaction only for low empathizers (Z = 2.30, p < .05).
Moreover, the two-way interaction for low empathizers replicated what we observed in previous
studies. When participants were unfamiliar with the experimenter, they were more likely to help
in the rough (71.51%) than the smooth condition (22.44%, Z = 1.99, p < .05; Figure 4a). In
contrast, there was no such difference in the willingness to help when participants were familiar
with the experimenter (41.97% vs. 75.85%, Z = 1.28, p = .20; Figure 4b). However, for high
empathizers, there was only a main effect of familiarity (Z = 2.26, p < .05). Although high
empathetic participants were less likely to help the unfamiliar experimenter (70.90%) versus the
familiar experimenter (97.79%), the haptic sensation had no impact on willingness to help (Z = -
.32, p > .7).
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Insert figure 4ab about here
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Discussion
This study provided additional support for the mediating role of empathy. As predicted,
for individuals who were chronically low in empathy, we replicated the previously observed
interaction between haptic sensation and target familiarity. However, such an interaction was
absent among chronically high empathizers, suggesting that high dispositional empathy overrode
the differential situational empathy elicited by haptic roughness.
STUDY 6: A FIELD EXPERIMENT OF STREET FUNDRAISING
28
In the final study, we aimed to replicate the above effects in a real-world situation. We
adopted the same donation context as used in studies 1 and 3, but conducted a real street
fundraising event involving passersby as participants. We partnered with the National Breast
Cancer Foundation to solicit donations in the fundraising event. To produce the unfamiliar
condition, we created a fictitious foundation named “National Sjögren's Foundation”.
Method
One hundred and thirty three pedestrians in the downtown area of a large North American
city participated in the study. We used a 2(charity type: familiar vs. unfamiliar) x 2(haptic
sensation: smooth vs. rough) between-subject design.
The experimenter who acted as a street fundraiser approached each participant
individually. Upon hearing a brief introduction about the organization from the experimenter, the
participant was asked to complete a one-page short survey on a clipboard, which served as the
haptic manipulation. Specifically, for the smooth condition, the back side of the clipboard was
covered with a piece of projection sheet. In contrast, for the rough condition, the back side of the
clipboard was covered with a piece of 60-grit sandpaper.
A pretest with 51 undergraduate students confirmed the effectiveness of the haptic
manipulation. They were asked to rate the roughness of the clipboards on a 1 (not at all) to 7
(very much) scale as per two questions i.e., “When ou are holding the clipboard, to what extent
do our hands feel rough and coarse?”, “To what extent do our hands feel smooth and sleek?”).
The two questions were averaged (with the second one reverse coded) to create a roughness
29
index α = .94). Results indicated that the clipboard with the sandpaper indeed felt rougher (M =
6.27) than the clipboard with the projection sheet (M = 2.13, F(1,49) = 533.60, p < .001).
In the one-page questionnaire, pedestrians first read a brief introduction of the foundation,
and then indicated whether they would donate, and if so, how much. To avoid peer pressure and
demand effect, participants were asked to complete the survey while the experimenter was
talking to other participants. And they were asked to put the donation in an attached envelope if
they offered to donate. At the end of the study, all the solicited donations were sent to the
National Breast Cancer Foundation.
Results and Discussion
To analyze the data, we first conducted a binary logistic regression with the dependent
variable as whether to donate (0=No, 1=Yes) and the independent variables as charity type,
haptic sensations, and their interaction. Consistent with previous results, there was a significant
interaction between the charity type and the haptic sensation (Wald χ2 = 4.52, p < .05). For the
unknown National Sjögren's Foundation, people who were holding a rough clipboard (25.7%)
were more likely to donate than those who were holding a smooth clipboard (3.1%, χ2(1) = 6.72,
p < .05; Figure 5a). Yet, for the well-known National Breast Cancer Foundation, people who
were holding a rough clipboard (29.4%) were equally likely to donate as those who were holding
a smooth clipboard (25.0%, χ2(1) = .16, p > .50; Figure 5b).
Next, we conducted a 2x2 ANOVA on the donation amount for those who actually
donated money. There was no treatment effect (ps > .14). The results again suggested that haptic
experiences could only influence the decision of whether to help. Once such a decision was made,
30
the haptic sensation did not seem to affect the degree of helping, which might be rooted from
certain deeper intrinsic characteristics.
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Insert figure 5ab about here
--------------------------------------------------------------
GENERAL DISCUSSION
In this research, we examine how the texture of the haptic input, namely, its smoothness
ersus roughness, affects people’s prosocial eha iors in a su sequent et unrelated helping
context. We hypothesize that exposure to the haptic sensation of roughness versus smoothness
enhances empathy, which subsequently leads to greater willingness to help. Further, we propose
an important boundary condition for the main effect, such that when the potential helper is
familiar with the helping target, empathy inherent in the interpersonal connection would override
any haptic effect, resulting in comparable level of helping likelihood. We also shed light to the
underlying process by demonstrating that the interactive effect of haptic sensation and
interpersonal familiarity on willingness to help is mediated by empathy.
Our hypotheses received systematic support from six studies, including laboratory,
neuroscience, and field data. Study 1 established the basic main effect by showing that haptic
sensation of roughness versus smoothness led to participants’ higher willingness to donate
towards two fictitious charities. Study 2 used direct measures of brain activity to demonstrate
that exposure to haptic roughness may enhance attention and sensitivity to other’s misfortune,
and this effect appeared to be a later, more deliberate cognitive process. Study 3 provided a
31
boundary condition by showing that such a main effect only existed towards unfamiliar targets.
Studies 4 and 5 demonstrated that empathy mediated the interactive effect between haptic
sensation and interpersonal familiarity. Finally, study 6 replicated our laboratory results in a real-
world fundraising event. Further, our data in studies 4 and 6 suggested that the haptic sensations
may onl affect people’s decision on whether to help or not, ut not the degree of help.
The current research makes two important theoretical contributions. First, it expands our
understanding of the constellation of factors influencing people’s willingness to help. Prior
research has primarily focused on the social and personality factors that affect a person's
likelihood to help. In contrast, we demonstrate that non-social factors, specifically, the haptic
sensation of roughness, can also have significant impact on helping behaviors.
Second, this research also advances our knowledge on haptic sensation, one of the least
studied sensations in behavioral research (Ackerman, Nocera, and Bargh 2010; Field 2010; Peck
and Childers 2008). Existing research in haptics has primarily focused on the issue of the
presence versus absence of touch (e.g., Krishna and Morrin 2008; Martin 2012; Peck and Shu
2009; Peck and Wiggins 2006). Thus, little attention has been directed to examine the haptic
attributes (e.g., texture; Lederman and Klatzky 1987), while touch is always present. Therefore,
this research seeks to fill the gap in the haptic literature by studying the impact of one haptic
attribute, namely, haptic texture (i.e., roughness vs. smoothness), on people’s actual eha iors in
a subsequent yet unrelated context.
Our findings also raise a number of interesting questions that merit future investigation.
First, it is important to examine whether all rough stimuli can induce empathy. In our
experiments, we used stimuli with moderate roughness. It is possible that an intensely rough
object might evoke a strong discomfort, overriding the empathy effect. Future research can seek
32
to identify the optimal degree of roughness that elicits the maximum level of empathy. Second,
having examined the texture of the haptic inputs, future research can investigate other haptic
attributes, such as hardness, weight and temperature, and their impact on people’s prosocial
behaviors and other important cognition and behaviors. Finally, future research can explore how
haptic and other senses might interactively affect cognition and behavior.
This research offers important implications for charitable institutions, and particularly
those that are less known and struggling with limited donation rates. Our findings suggest that
interjecting a little roughness into their outreach materials, for example, could be an innovative
and cost-effective approach to increase empathy levels and thus ultimately enhance helping
likelihood and donation rates. Our findings suggest that incidental exposure to rough haptic
sensations has the capacity to systematically heighten our propensity for prosociality.
33
References
Aaker, Jennifer. L. and Satoshi Akutsu (2009), “Why do people give? The role of identity in
giving,” Journal of Consumer Psychology, 19, 267-70.
Ackermann, Joshua. M., Christopher C. Nocera, and John A. Bargh (2010), “Incidental haptic
sensations influence social judgments and decisions,” Science, 328, 1712-15.
Bagozzi, Richard. P. and David J. Moore (1994), “Public service advertisements: emotions and
empathy guide prosocial behavior,” Journal of Marketing, 58(1), 56-70.
Baron, Robert A. (1997), “The sweet smell of…helping: effects of pleasant am ient fragrance on
prosocial behavior in shopping malls,” Personality and Social Psychology Bulletin,
23(5), 498 -503.
Baston, C. Daniel (1991), The altruism question: Toward a social-psychological answer.
Hillsdale, NJ: Lawrence Erlbaum.
Batson, C. Daniel., Shannon Early, and Giovanni Salvarani (1997), “Perspective Taking:
Imagining How Another Feels versus Imagining How You Would Feel,” Personality and
Social Psychology Bulletin, 23 (7), 751–58.
Batson, C. Daniel., David A. Lishner, Amy Carpenter, Luis Dulin, Sanna Harjusola-Webb, E. L.
Stocks, Shawna Gale, Omar Hassan, and Brenda Samput (2003), “. . . As You Would
Ha e Them o Unto You”: oes Imagining Yourself in the Other’s Place Stimulate
Moral Action?,” Personality and Social Psychology Bulletin, 29 (4), 1190–201.
34
Bendapudi, Neeli, Surendra N. Singh and Venkat Bendapudi (1996), “Enhancing helping
behavior: an integrative framework for promotion planning,” Journal of Marketing, 60(3),
33-49.
Citrin, Alka Varma, Donald E. Stem Jr., Eric R. Spangenberg, and Michael J. Clark (2003),
“Consumer Need for Tactile Input: An Internet Retailing Challenge,” Journal of Business
Research, 56 (11), 915–22.
Coke, Jay S., C. Daniel Batson, and Katherine McDavis (1978), “Empathic Mediation of
Helping: A Two-Stage Model,” Journal of Personality and Social Psychology, 36 (7),
752–66.
Crusco, April H. and Christopher G. Wetzel (1984), “The Midas touch: the effects of
interpersonal touch on restaurant tipping,” Personality and Social Psychology Bulletin,
10, 512–17.
Decety, Jean and Claus Lamm (2006), “Human empathy through the lens of social
neuroscience,” The Scientific World Journal, 6, 1146-63.
peault, Alexandra, El-Mehdi Meftah, and C. Elaine Chapman (2009), “Tactile perception of
roughness: raised-dot spacing, densit and disposition,” Experimental Brain Research,
197, 235-44.
Dovidio, John F., Judith L. Allen, and David A. Schroeder (1990), “Specificity of empathy-
induced helping: evidence for altruistic motivation,” Journal of Personality and Social
Psychology, 59(2), 249-60.
35
Dovidio, John F., Samuel L. A. Gaertner, Ana Validzic, Kimberly Matoka, Brenda Johnson, and
Stac Frazier 1997), “Extending the Benefits of Recategorization: Evaluations, Self-
Disclosure, and Helping,” Journal of Experimental Social Psychology, 33 (4), 401–20.
Dunn, Elizabeth W., Lara B. Aknin, and Michael I. Norton (2008), ‘Spending money on others
promotes happiness,” Science, 319, 1687-88.
Eisenberg, Nancy and Paul A. Miller (1987), “The relation of empathy to prosocial and related
behaviors,” Psychological Bulletin, 101, 91-119.
Erceau, Damien and Nicolas Guéguen (2007) “Tactile contact and evaluation of the toucher,”
Journal of Social Psychology, 147, 441–44.
Fan, Yan and Shihui Han (2008), “Temporal dynamic of neural mechanisms involved in
empathy for pain: an event-related brain potential study,” Neuropsychologia, 46, 160-73.
Field, Tiffany (2010), “Touch for socioemotional and physical well- eing: a re iew,”
Developmental Review, 30, 367-83.
Fischer, Jeffrey D., Marvin Rytting, and Richard Heslin (1976), “Hands touching hands:
affective and evaluative effects of interpersonal touch,” Sociometry, 39, 416–21.
Flippen, Annette R., Harvey A. Hornstein, William E. Siegal, and Eben A. Weitzman (1996), “A
Comparison of Similarity and Interdependence as Triggers for Ingroup Formation,”
Personality and Social Psychology Bulletin, 22, 882-93.
Gallace, Alberto and Charles Spence (2010), “The science of interpersonal touch: An overview,”
Neuroscience and Biobehavioral Reviews, 34(2), 246-59.
36
Greitemeyer, Tobias and Silvia Osswald (2010), “Effects of prosocial video games on prosocial
behavior,” Journal of Personality and Social Psychology, 98, 11−21.
Grohmann, Bianca, Eric R. Spangenberg, and David E. Sprott (2007), “The Influence of Tactile
Input on the Evaluation of Retail Product Offerings,” Journal of Retailing, 83 (2), 237–45.
Goubert, Liesbet, et al. (2005), “Facing others in pain: the effects of empathy,” Pain, 118, 285-
88.
Gu, Xiaosi and Shihui Han (2007), “Attention and reality constraints on the neural processes of
empathy for pain,” NeuroImage, 36, 256–67.
Harvey, James W. (1990), “Benefit segmentation for fundraisers,” Journal of the Academy of
Marking Science, 18 (1), 77-86.
Hayes, Andrew F. (2012), “PROCESS: A versatile computational tool for observed variable
mediation, moderation, and conditional process modeling [White paper],” Retrieved from
http://www.afhayes.com/public/process2012.pdf
Hertenstein, Matthew J., Dacher Keltner, Betsy App, Brittany A. Bulleit, and Ariane R. Jaskolka
(2006), “Touch communicates distinct emotions,” Emotion, 6, 528–33.
Hoffman, Martin L. (1982), “Development of prosocial motivation: Empathy and guilt,” in The
development of prosocial behavior, ed. Nancy Eisenberg, New York: Academic Press,
281-313.
Hornstein, Harvey A. (1976), Cruelty and kindness: A new look at aggression and altruism,
Englewood Cliffs, NJ: Prentice Hall.
37
Irwin, Julie R. and Gary H. McClelland 001), “Misleading Heuristics and Moderated Multiple
Regression Models,” Journal of Marketing Research, 38 (1), 100–109.
Klatzky, Robert L. and Susan J. Lederman (1992), “Stages of Manual Exploration in Haptic
Object Identification,” Perception & Psychophysics, 52 (6), 661-70.
__________ (1993), “Toward a Computational Model of Constraint- Driven Exploration and
Haptic Object Identification,” Perception, 22 (5), 597-621.
Klatzky, Robert L, Susan J. Lederman, and Catherine Reed (1987), “There´s more to touch than
meets the eye: Relative salience of object dimensions for touch with and without vision,”
Journal of Experimental Psychology: General, 116(4), 356-69.
Krebs, Dennis L. (1970), “Altruism—an Examination of the Concept and a Review of the
Literature,” Psychological Bulletin, 73 (April), 258–302.
___________ (1975), “Empathy and Altruism,” Journal of Personality and Social Psychology,
32 (6), 1134–46.
Krishna, Aradhna and Maureen Morrin (2008), “Does Touch Affect Taste? The Perceptual
Transfer of Product Container Haptic Cues,” Journal of Consumer Research, 34 (6),
807–18.
Lamm, Claus, Howard C. Nusbaum, Andrew N. Meltzoff, and Jean Decety (2007), “What are
you feeling? Using functional magnetic resonance imaging to assess the modulation of
sensory and affective responses during empathy for pain,” PLoS ONE, 12, e1292.
38
Lawrence, Michael A., Ryo Kitada, Roberta L. Klatzky, and Susan J. Lederman (2007), “Haptic
roughness perception of linear gratings ia are finger or rigid pro e,” Perception, 36,
547–57.
Lederman, Susan J. (1983), “Tactual roughness perception: spatial and temporal determinants,”
Canadian Journal of Psychology, 37(4), 498–511.
Lederman, Susan J. and Roberta L. Klatzky (1987), “Hand Movements: A Window into Haptic
Object Recognition,” Cognitive Psychology, 19 (3), 342-68.
Li, Wei and Shihui Han (2010), “Perspective taking modulates event-related potentials to
perceived pain,” Neuroscence Letters, 469, 328-32.
Loewenstein, George and Deborah A. Small (2007), “The Scarecrow and the Tin Man: The
Vicissitudes of Human S mpath and Caring,” Review of General Psychology, 11 (2),
112–26.
Martin, Brett A.S. 01 ), “A Stranger’s Touch: Effects of Accidental Interpersonal Touch on
Consumer Evaluations and Shopping Time,” Journal of Consumer Research, 39(1), 174-
84.
Mayer, John D., David R. Caruso and Peter Salovey (1999), “Emotional intelligence meets
traditional standards for an intelligence,” Intelligence, 27(4), 267-98.
McCabe, Deborah Brown and Stephen M. Nowlis (2003), “The Effect of Examining Actual
Products or Product Descriptions on Consumer Preference,” Journal of Consumer
Psychology, 13 (4), 431–39.
39
Nelson, Leif D. and Michael I. Norton (2005), “From student to superhero: Situational primes
can shape future helping,” Journal of Experimental Social Psychology, 41, 423–30.
North, Adrian C., Mark Tarrant, and David J. Hargreaves (2004), “The effect of music on
helping behavior: a field study,” Environment and Behavior, 36(2), 266-75.
Peck, Joann and Terry L. Childers (2003a), “To Have and To Hold: The Influence of Haptic
Information on Product Judgments,” Journal of Marketing, 67, 35–48.
____________ (2003b), “Indi idual ifferences in Haptic Information Processing: The “Need
for Touch” Scale,” Journal of Consumer Research, 30, 430–442.
_____________ (2008), “Effects of Sensory Factors on Consumer Behaviors,” in Handbook of
Consumer Psychology, ed. Frank Kardes, Curt Haugtvedt, and Paul Herr, Mahwah, NJ:
Erlbaum.
Peck, Joann and Jennifer Wiggins (2006), “It just feels good: Consumers' affective response to
touch and its influence on attitudes and eha ior,” Journal of Marketing, 70(4), 56-69
Peck, Joann and Suzanne B. Shu (2009), “The Effect of Mere Touch on Perceived Ownership,”
Journal of Consumer Research, 36 (3), 434–47.
Sedikides, Constantine, W. Keith Campbell, Glenn D. Reeder, and Andrew J. Elliot 1999), “The
Relationship Closeness Induction Task,” Representative Research in Social Psychology,
23, 1–4.
Singer, Tania and Claus Lamm (2009), “The social neuroscience of empathy,” Annals of the
New York Academy of Sciences, 1156, 81–96.
40
Singer, Tania, et al. (2004), “Empathy for pain involves the affective but not sensory
components of pain,” Science, 303, 1157-62.
Small, Deborah A. and Uri Simonsohn 008), “Friends of Victims: Personal Experience and
Prosocial Behavior,” Journal of Consumer Research, 35 (3), 532–42.
Twenge, Jean M., Roy F. Baumeister, C. Nathan DeWall, Natalie J. Ciarocco, and Michael J.
Bartels (2007), “Social exclusion decreases prosocial behavior,” Journal of Personality
and Social Psychology, 92, 56–66.
U.S. Bureau of Labor Statistics, Volunteering in the United States (2010;
http://www.bls.gov/news.release/volun.nr0.htm).
Weinstein, Netta and Richard M. Ryan (2010), “When Helping Helps: Autonomous Motivation
for Prosocial Behavior and Its Influence on Well-Being for the Helper and Recipient,”
Journal of Personality and Social Psychology, 98, 222-44.
Williams, Lawrence E. and John A. Bargh (2008), “Experiencing physical warmth promotes
interpersonal warmth,” Science, 322, 606–07.
Wispé, Lauren (1986), “The distinction between sympathy and empathy: To call forth a concept,
a word is needed,” Journal of Personality and Social Psychology, 50, 314–21.
Zahn-Waxler, Carolyn and Marian Radke-Yarrow (1990), “The Origins of Empathic Concern,”
Motivation and Emotion, 14 (June), 107–30.
41
Table 1. Performance data from study 2. The values shown for RTs are in ms.
Haptic Sensation Image Type
Measure Painful Neutral
% "painful"
responses
Smooth 0.916 0.031
Rough 0.915 0.029
RTs Smooth 748 747
Rough 761 753
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FIGURE 1. STIMULI AND DATA FROM STUDY 2
(A) Examples of the neutral and painful image conditions. (B) The group-averaged ERP
waveforms as a function of condition. The three separate time windows of statistical analysis are
indicated by the vertical dashed lines. (C) Mean amplitudes and standard errors of the ERP
responses across conditions and time windows shown in (B). N = neutral image, P = painful
image, * = t value of p < 0.01, ns = non-significant t value.
43
FIGURE 2: INTERACTION BETWEEN FAMILIARITY AND HAPTIC SENSATION ON
WILLINGNESS TO DONATE (STUDY 3)
44
FIGURES 3A: HELP AN UNFAMILIAR CONFEDERATE (STUDY 4)
FIGURES 3B: HELP A FAMILIAR CONFEDERATE (STUDY 4)
45
FIGURES 4A. LOW EMPATHIZERS HELP AN UNFAMILIAR EXPERIMENTER
(STUDY 5)
FIGURES 4B. LOW EMPATHIZERS HELP A FAMILIAR EXPERIMENTER (STUDY 5)
46
FIGURES 5A. ONATE TO NATIONAL SJÖGREN’S FOUN ATION STU Y 6)
FIGURES 5B. DONATE TO NATIONAL BREAST CANCER FOUNDATION (STUDY 6)